Counterselection of GATC sequences in enterobacteriophages by the components of the methyl-directed mismatch repair system

Summary Weak to severe deficit of GATC sequences in the DNA of enterobacteriophages appears to be correlated with their undermethylation during growth indam ⁺ (GATC ade-methylase) bacteria. This observation is corroborated by the sequence analysis showing no evidence for site-specific mutagenicity of 6meAde. The MutH protein of the methyl-directed mismatch repair system recognizes and cleaves the undermethylated GATC sequences in the course of mismatch repair. To enquire whether the MutH function of the methyldirected mismatch repair system participates in counterselection of GATC sequences in enterobacteriophages, we have studied the yield of bacteriophage X174 containing either 0, 1, or 2 GATC sequences, in wild type,dam, andmut (H, L, S, U) Escherichia coli. Following transfection with unmethylated DNA containing two GATC sequences, a net decrease in the yield of infective particles was observed in all bacterialmutH ⁺ dam^– strains, whereas no detectable decrease was observed in bacteria infected by DNA without GATC sequence. This effect of the MutH function is maximum in wild type andmutL andmutS bacteria whereas the effect is not significant inmutU bacteria, suggesting an interaction of the, helicase II with the MutH protein.However, indam ⁺ bacteria, the presence of GATC sequences leads to an increased yield of infective particles. The effect of GATC sequence and its Dam methylation system on phage yield inmutH ^– bacteria reveals that methylated GATC sequences are advantageous to the phage. These results suggest that the methyl-directed mismatch repair system, and in particular its MutH protein, may have participated in severe counterselection of GATC sequences from enterobacteriophages, presumably, by DNA cleavage or by interfering with DNA replication or packaging when GATC sequences are undermethylated. Coevolution of the Dam and MutH proteins could then account for the loss of GATC sequences from DNA of bacteriophages growing indam ⁺ hosts.     

Methyl directed DNA mismatch repair inVibrio cholerae

Mismatches in DNA occur either due to replication error or during recombination between homologous but non-identical DNA sequences or due to chemical modification of bases. The mismatch in DNA, if not repaired, result in high spontaneous mutation frequency. The repair has to be in the newly synthesized strand of the DNA molecule, otherwise the error will be fixed permanently. Three distinct mechanisms have been proposed for the repair of mismatches in DNA in prokaryotic cells and gene functions involved in these repair processes have been identified. The methyl-directed DNA mismatch repair has been examined inVibrio cholerae, a highly pathogenic gram negative bacterium and the causative agent of the diarrhoeal disease cholera. The DNA adenine methyltransferase encoding gene (dam) of this organism which is involved in strand discrimination during the repair process has been cloned and the complete nucleotide sequence has been determined.Vibrio cholerae dam gene codes for a 21.5 kDa protein and can substitute for theEscherichia coli enzyme. Overproduction ofVibrio cholerae Dam protein is neither hypermutable nor lethal both in Escherichia coli andVibrio cholerae. WhileEscherichia coli dam mutants are sensitive to 2-aminopurine,Vibrio cholerae 2-aminopurine sensitive mutants have been isolated with intact GATC methylation activity. The mutator genesmutS andmutL involved in the recognition of mismatch have been cloned, nucleotide sequence determined and their products characterized. Mutants ofmutS andmutL ofVibrio cholerae have been isolated and show high rate of spontaneous mutation frequency. ThemutU gene ofVibrio cholerae, the product of which is a DNA helicase II, codes for a 70 kDa protein. The deduced amino acid sequence of themutU gene hs all the consensus helicase motifs. The DNA cytosine methyltransferase encoding gene (dam) ofVibrio cholerae has also been cloned. Thedcm gene codes for a 53 kDa protein. This gene product might be involved in very short patch (VSP) repair of DNA mismatches. The vsr gene which is directly involved in VSP repair process codes for a 23 kDa protein. Using these information, the status of DNA mismatch repair inVibrio cholerae will be discussed.     

Asymmetric repair of bacteriophage T7 heteroduplex DNA

Summary Heteroduplex DNA molecules were prepared in vitro using one strand of DNA carrying a point mutation and one strand of the corresponding wild-type DNA. The heteroduplex DNA was transfected into competent bacteria and the progeny genotypes in the resulting infective centers were determined. From the results were conclude that about 80% of all transfected DNA molecules are repaired before DNA replication starts. This fraction of repaired DNA is independent of the location of the mismatched nucleotide pair. However, mismatch correction occurs preferentially on the H strand of the heteroduplex DNA.The repair does not depend on a known phage coded function but requires the active bacterial genes mut U, mut H, mut S and probably mut L.     

d(GATC) sequences influence Escherichia coli mismatch repair in a distance-dependent manner from positions both upstream and downstream of the mismatch

The role of d(GATC) sites in determining the efficiency of methyl-directed mismatch repair in Escherichia coli was investigated. Transfection of host bacteria, both proficient and deficient in mismatch repair, with a series of artificially constructed M13 heteroduplexes showed that a decrease in the total number of d(GATC) sequences within these vectors lowered the efficiency of repair in vivo. Single hemimethylated d(GATC) sequences were still able to direct the correction event to the unmethylated strand, providing that the mismatch to d(GATC) site distance was shorter than approximately 1 kb. In excess of this distance, the effect of hemimethylated d(GATC) sites on mismatch correction was almost unnoticeable. The directionality of the repair event could be dictated by d(GATC) sequences situated both upstream and downstream of the mispair, suggesting that this important antimutagenic pathway can proceed bidirectionally.     

Effect of proofreading and dam-instructed mismatch repair systems on N4-hydroxycytidine-induced mutagenesis

Summary The role of the proofreading (35 exonuclease) function of T4 DNA polymerase and the mismatch repair system ofE. coli on N⁴-hydroxycytidine (oh⁴Cyd)¹ induced mutagenesis was investigated. oh⁴Cyd-induced mutation is strongly suppressed when the proofreading activity increases as a result of the presence oftsCB87-antimutator polymerase or elevated temperature (43° C vs 30° C). Mutagenic activity of oh⁴Cyd, however, is little, if at all, affected by the presence of thetsLB56 mutator allele of T4 DNA polymerase with suppressed proofreading activity. This leads to the conclusion that oh⁴C nucleotides are not frequently removed by proofreading activity of wild-type T4 DNA polymerase. The number of mutations induced by oh⁴Cyd increases 3- to 5-fold due to damage of the genesmutS,mutL,uvrE, but notmutR.Dam ^- cells are more sensitive to, and hypermutable by, oh⁴Cyd in comparison withdam ⁺ cells. This is compatible with the notion that oh⁴C residues are recognised and excised by mismatch repair enzymes. The results indicate thath neither the proofreading function of T4 DNA polymerase, nor the mismatch repair enzymes, are responsible for the high specificity of oh⁴Cyd which causes ATGC transition.     

2-Aminopurine and 5-bromouracil induce alleviation of type I restriction in Escherichia coli: Mismatches function as inducing signals?

Summary The EcoK restriction of unmodified phage is 1000-fold alleviated in Escherichia coli grown in the presence of base analogs 2-aminopurine (2AP) and 5-bromouracil (5BU). 2AP treatment of bacteria affects specificially the type I restriction systems (EcoA, EcoB, EcoD and EcoK) and does not influence type II (EcoRI) and type III (EcoP1) restriction. 2AP-induced alleviation of restriction occurs in bacteria which are deficient in the SOS response (recA and lexA) and mismatch repair (mutH, mutL and mutS) and can be distinguished from the alleviation of restriction observed in dam ^- strains. We suggest that mismatches induced by 2AP and 5BU may function as an inducing signal for the alleviation of restriction observed in the presence of base analogs.     

Tyr212: a key residue involved in strand discrimination by the DNA mismatch repair endonuclease MutH

The molecular mechanism of how the dam-methylation status of the DNA is recognized during DNA mismatch repair by the strand discrimination endonuclease MutH is not known. A comparison of the crystal structure of MutH with those of co-crystal structures of several restriction endonucleases, together with a multiple sequence alignment of MutH and related proteins suggested that Phe94, Arg184 and Tyr212 could be involved in discrimination between a methylated or unmethylated adenine in the d(GATC) sequence. A mutational analysis revealed that the variants R184A and Y212S, but not F94A, were substantially reduced in their ability to complement a mismatch repair deficiency in a mutH(-) Escherichia coli strain. In vitro, R184A displayed a strongly reduced endonuclease activity, whereas the Y212S variant has almost completely lost its preference for cleaving the unmethylated strand at hemimethylated d(GATC) sites. Furthermore, the Y212 variant can cleave fully methlyated d(GATC) sites at a comparable rate to unmethylated d(GATC) sites. This demonstrates that Tyr212 is an important, if not the only amino acid residue in MutH for sensing the methylation status of the DNA.     

Methyl-directed DNA mismatch repair in Escherichia coli

Some of the molecular aspects of methyl-directed mismatch repair in E. coli have been characterized. These include: mismatch recognition by mutS protein in which different mispairs are bound with different affinities; the direct involvement of d(GATC) sites; and strand scission by mutH protein at d(GATC) sequences with strand selection based on methylation of the DNA at those sites. In addition, communication over a distance between a mismatch and d(GATC) sites has been implicated. Analysis of mismatch correction in a defined system (Lahue et al., unpublished) should provide a direct means to further molecular aspects of this process.     

Escherichia coli frameshift mutation rate depends on the chromosomal context but not on the GATC content near the mutation site

Different studies have suggested that mutation rate varies at different positions in the genome. In this work we analyzed if the chromosomal context and/or the presence of GATC sites can affect the frameshift mutation rate in the Escherichia coli genome. We show that in a mismatch repair deficient background, a condition where the mutation rate reflects the fidelity of the DNA polymerization process, the frameshift mutation rate could vary up to four times among different chromosomal contexts. Furthermore, the mismatch repair efficiency could vary up to eight times when compared at different chromosomal locations, indicating that detection and/or repair of frameshift events also depends on the chromosomal context. Also, GATC sequences have been proved to be essential for the correct functioning of the E. coli mismatch repair system. Using bacteriophage heteroduplexes molecules it has been shown that GATC influence the mismatch repair efficiency in a distance- and number-dependent manner, being almost nonfunctional when GATC sequences are located at 1 kb or more from the mutation site. Interestingly, we found that in E. coli genomic DNA the mismatch repair system can efficiently function even if the nearest GATC sequence is located more than 2 kb away from the mutation site. The results presented in this work show that even though frameshift mutations can be efficiently generated and/or repaired anywhere in the genome, these processes can be modulated by the chromosomal context that surrounds the mutation site.     

Influence of GATC sequences on Escherichia coli DNA mismatch repair in vitro.

The effect of the number and position of DNA adenine methylation (dam) sites, i.e., d(GATC) sequences, on mismatch repair in Escherichia coli was investigated. The efficiency of repair was measured in an in vitro assay which used an f1 heteroduplex containing a G/T mismatch within the single EcoRI site. Both an increase in the number of dam sites and a shortened distance between dam site and mismatched site increased the efficiency of mismatch repair. The sequences adjacent to d(GATC) also affected the efficiency of methylation-directed mismatch repair. Furthermore, heteroduplexes with one extra dam site located close to either the 5' or 3' end of the excised base increased the repair efficiency to about the same extent. The findings suggest that the mismatch repair pathway has no preferred polarity.     

Exo1 independent DNA mismatch repair involves multiple compensatory nucleases

Functional DNA mismatch repair (MMR) is essential for maintaining the fidelity of DNA replication and genetic stability. In hematopoiesis, loss of MMR results in methylating agent resistance and a hematopoietic stem cell (HSC) repopulation defect. Additionally MMR failure is associated with a variety of human malignancies, notably Lynch syndrome. We focus on the 5′ → 3′ exonuclease Exo1, the primary enzyme excising the nicked strand during MMR, preceding polymerase synthesis. We found that nuclease dead Exo1 mutant cells are sensitive to the O6-methylguanine alkylating agent temozolomide when given with the MGMT inactivator, O6benzylguanine (BG). Additionally we used an MMR reporter plasmid to verify that Exo1^mut MEFs were able to repair G:T base mismatches in vitro. We showed that unlike other MMR deficient mouse models, Exo1^mut mouse HSC did not gain a competitive survival advantage post temozolomide/BG treatment in vivo. To determine potential nucleases implicated in MMR in the absence of Exo1 nuclease activity, but in the presence of the inactive protein, we performed gene expression analyses of several mammalian nucleases in WT and Exo1^mut MEFs before and after temozolomide treatment and identified upregulation of Artemis, Fan1, and Mre11. Partial shRNA mediated silencing of each of these in Exo1^mut cells resulted in decreased MMR capacity and increased resistance to temozolomide/BG. We propose that nuclease function is required for fully functional MMR, but a portfolio of nucleases is able to compensate for loss of Exo1 nuclease activity to maintain proficiency.     

Initiation of methyl-directed mismatch repair.

Escherichia coli MutH possesses an extremely weak d(GATC) endonuclease that responds to the state of methylation of the sequence (Welsh, K. M., Lu, A.-L., Clark, S., and Modrich, P. (1987) J. Biol. Chem. 262, 15624-15629). MutH endonuclease is activated in a reaction that requires MutS, MutL, ATP, and Mg2+ and depends upon the presence of a mismatch within the DNA. The degree of activation correlates with the efficiency with which a particular mismatch is subject to methyl-directed repair (G-T greater than G-G greater than A-C greater than C-C), and activated MutH responds to the state of DNA adenine methylation. Incision of an unmethylated strand occurs immediately 5' to a d(GATC) sequence, leaving 5' phosphate and 3' hydroxy termini (pN decreases pGpAp-TpC). Unmethylated d(GATC) sites are subject to double strand cleavage by activated MutH, an effect that may account for the killing of dam- mutants by 2-aminopurine. The mechanism of activation apparently requires ATP hydrolysis since adenosine-5'-O-(3-thiotriphosphate) not only fails to support the reaction but also inhibits activation promoted by ATP. The process has no obligate polarity as d(GATC) site incision by the activated nuclease can occur either 3' or 5' to the mismatch on an unmethylated strand. However, activation is sensitive to DNA topology. Circular heteroduplexes are better substrates than linear molecules, and activity of DNAs of the latter class depends on placement of the mismatch and d(GATC) site within the molecule. MutH activation is supported by a 6-kilobase linear heteroduplex in which the mismatch and d(GATC) site are centrally located and separated by 1 kilobase, but a related molecule, in which the two sites are located near opposite ends of the DNA, is essentially inactive as substrate. We conclude that MutH activation represents the initiation stage of methyl-directed repair and suggest that interaction of a mismatch and a d(GATC) site is provoked by MutS binding to a mispair, with subsequent ATP-dependent translocation of one or more Mut proteins along the helix leading to cleavage at a d(GATC) sequence on either side of the mismatch.     

Establishment,counts, and identification of the fibrolytic microflora in the digestive tract of rabbit. Influence of feed cellulose content

Dam-mediated adenine methylation at GATC sites can interfere with gene expression. By use oflacZ fusion technology, the efficiency oftrpR andtrpS promoters (which contain a GATC site) and oftrp (the target of TrpR repressor) was analyzed indam ⁺ anddam ^– backgrounds. In exponentially growing cells, thedam mutation leads to an increased activity oftrpR promoter but does not affecttrpS ortrp promoters. The Dam-mediated induction oftrpR was, however, found to be repressed bytrpR-mediated autoregulation. In contrast,trp-lacZ directed-galactosidase activity was increased at least sixfold indam ^– cells in late logarithmic growth phase. Indam ⁺ cells, expression oftrp-lacZ was similarly late-growth-phase induced, albeit to a reduced extent. Hence, we propose that enhancement of growth phase-dependent gene induction constitutes a previously unidentified trait ofdam mutation. This finding is discussed in the context of the pleiotropic phenotype ofdam mutation.     

Gap formation is associated with methyl-directed mismatch correction under conditions of restricted DNA synthesis

A covalently closed, circular heteroduplex containing a G-T mismatch and a single hemimethylated d(GATC) site is subject to efficient methyl-directed mismatch correction in Escherichia coli extracts when repair DNA synthesis is severely restricted by limiting the concentration of exogenously supplied deoxyribonucleoside-5'-triphosphates or by supplementing reactions with chain-terminating 2',3'-dideoxynucleoside triphosphates. However, repair under these conditions results in formation of a single-strand gap in the region of the molecule containing the mismatch and the d(GATC) site. These findings indicate that repair DNA synthesis required for methyl-directed correction can initiate in the vicinity of the mispair, and they are most consistent with a repair reaction involving 3'----5' excision (or strand displacement) from the d(GATC) site followed by 5'----3' repair DNA synthesis initiating in the vicinity of the mismatch.     

Processing of mispaired and unpaired bases in heteroduplex DNA in E. coli

Bacteriophage lambda and phi X 174 DNAs, carrying sequenced mutations, have been used to construct in vitro defined species of heteroduplex DNA. Such heteroduplex DNAs were introduced by transfection, as single copies, into E. coli host cells. The progeny of individual heteroduplex molecules from each infective center was analyzed. The effect of the presence of GATC sequences (phi X 174 system) and of their methylation (lambda system) was tested. The following conclusions can be drawn: some mismatched base pairs trigger the process of mismatch repair, causing a localized strand-to-strand information transfer in heteroduplex DNA: transition mismatches G:T and A:C are efficiently repaired, whereas the six transversion mismatches are not always readily recognized and/or repaired. The recognition of transversion mismatches appears to depend on the neighbouring nucleotide sequence; single unpaired bases (frameshift mutation "mismatches") are recognized and repaired, some equally efficiently on both strands (longer and shorter), some more efficiently on the shorter (-1) strand; large non-homologies (about 800 bases) are not repaired by the Mut H, L, S, U system, but some other process repairs the non-homology with a relatively low efficiency; full methylation of GATC sequences inhibits mismatch repair on the methylated strand: this is the chemical basis of strand discrimination (old/new) in mismatch correction; unmethylated GATC sequences appear to improve mismatch repair of a G:T mismatch in phi X 174 DNA, but there may be some residual mismatch repair in GATC-free phi X 174, at least for some mismatches.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mutational analyses of dinucleotide and tetranucleotide microsatellites in Escherichia coli: influence of sequence on expansion mutagenesis

Mutagenesis at [GT/CA]₁₀, [TC/AG]₁₁ and [TTCC/AAGG]₉ microsatellite sequences inserted in the herpes simplex virus thymidine kinase (HSV-tk) gene was analyzed in isogenic mutL⁺ and mutL^– Escherichia coli. In both strains, significantly more expansion than deletion mutations were observed at the [TTCC/AAGG]₉ motif relative to either dinucleo­tide motif. As the HSV-tk coding sequence contains an endogenous [G/C]₇ mononucleotide repeat and ~1000 bp of unique sequence, we were able to compare mutagenesis among various sequence motifs. We observed that the relative risk of mutation in E.coli is: [TTCC/AAGG]₉ > [GT/CA]₁₀ ~ [TC/AG]₁₁ > unique ~ [G/C]₇. The mutation frequency varied 1400-fold in mutL⁺ cells between the tetranucleotide motif and the mononucleotide motif, but only 50-fold in mutL^– cells. The [G/C]₇ sequence was destabilized the greatest and the tetranucleotide motif the least by loss of mismatch repair. These results demonstrate that the quantitative risk of mutation at various microsatellites greatly depends on the DNA sequence composition. We suggest alternative models for the production of expansion mutations during lagging strand replication of the [TTCC/AAGG]₉ microsatellite.     

GATC sequence and mismatch repair in Escherichia coli.

The Escherichia coli mismatch repair system greatly improves DNA replication fidelity by repairing single mispaired and unpaired bases in newly synthesized DNA strands. Transient undermethylation of the GATC sequences makes the newly synthesized strands susceptible to mismatch repair enzymes. The role of unmethylated GATC sequences in mismatch repair was tested in transfection experiments with heteroduplex DNA of phage phi 174 without any GATC sequence or with two GATC sequences, containing in addition either a G:T mismatch (Eam+/Eam3) or a G:A mismatch (Bam+/Bam16). It appears that only DNA containing GATC sequences is subject to efficient mismatch repair dependent on E. coli mutH, mutL, mutS and mutU genes; however, also in the absence of GATC sequence some mut-dependent mismatch repair can be observed. These observations suggest that the mismatch repair enzymes recognize both the mismatch and the unmethylated GATC sequence in DNA over long distances. The presence of GATC sequence(s) in the substrate appears to be required for full mismatch repair activity and not only for its strand specificity according to the GATC methylation state.     

Repair of 8-methoxypsoralen photoinduced cross-links in yeast

Summary The repair of interstrand cross-links induced by 8-methoxypsoralen plus UVA (365 nm) radiation DNA was analyzed in diploid strains of the yeast Saccharomyces cerevisiae. The strains employed were the wild-type D₇ and derivatives homozygous for the rad18-1 or the rad3-12 mutation. Alkaline step-elution and electron microscopy were performed to follow the process of induction and removal of photoinduced crosslinks. In accordance with previous reports, the D₇ rad3-12 strain failed to remove the induced lesions and could not incise cross-links. The strain D₇ rad18-1 was nearly as efficient in the removal of 8-MOP photoadducts after 2 h of post-treatment incubation as the D₇ RAD⁺ wild-type strain. However, as demonstrated by alkaline step-elution and electron microscopic analysis, the first incision step at DNA cross-links was three times more effective in D₇ rad18-1 than in D₇ RAD⁺. This is consistent with the hypothesis that the RAD18 gene product is involved in the filling of gaps resulting from persistent non-informational DNA lesions generated by the endonucleolytic processing of DNA cross-links. Absence of this gene product may lead to extensive strand breakage and decreased recognition of such lesions by structural repair systems.     

Reversal by DNA amplifications of an unusual mutation blocking alkane and alcohol utilization in Pseudomonas putida

Summary We analyzed the reversion of strains carrying alk208, a mutation in the alkBAC (alkane utilization) region of the Pseudomonas CAM-OCT plasmid. Reversion of alk208 was stimulated 25 to 75-fold by small doses of UV-irradiation. All alkane hydroxylase-positive (AlkB⁺) revertants proved to be aliphatic alcohol dehydrogenasepositive (AlkC⁺) as well, whereas AlkC⁺ revertants could be either AlkB⁺ or AlkB^-. Most of the AlkB^- AlkC⁺ partial revertants produced AlkC^- segregants at measurable frequencies. UV-irradiation substantially increased the rate of AlkC^- segregation. Most segregants reverted to AlkB⁺ or AlkC⁺ at frequencies similar to the original alk208 strain. Dot blot hybridization analyses using cloned probes from various regions of CAM-OCT revealed that the partial revertants contained specific amplications of alk DNA. The endpoints of these amplifications mapped in at least two regions. AlkC^- segregants had lost the DNA amplifications.     

Effect of uracil situated in the vicinity of a mispair on the directionality of mismatch correction in Escherichia coli.

We wanted to establish whether strand breaks and gaps, arising during the removal of uracil from newly-synthesized DNA, can be utilized as strand discrimination signals by the methyl-directed mismatch repair system of Escherichia coli. For this purpose, we constructed a series of M13 heteroduplexes that contained a single uracil residue situated either upstream or downstream from a G/T or an A/C mispair. Transfections of these constructs into E. coli strains, either proficient of deficient in mismatch or uracil repair, allowed us to follow the fate of these mispairs in vivo. Our data show that the intermediates of uracil repair cannot substitute for the strand-discrimination signals generated by the MutH protein, which is thought to initiate the methyl-directed mismatch repair process by nicking the unmethylated strand of a newly-synthesized DNA duplex at d(GATC) sites. However, processing of uracil residues situated upstream from the mispair was shown to reduce the yield of the progeny phage arising from the uracil-containing strand, presumably as a result of co-repair of the base analogue and the mispair.